public: BVHHandle item_add(T *p_userdata, bool p_active, const BOUNDS &p_aabb, int32_t p_subindex, uint32_t p_tree_id, uint32_t p_tree_collision_mask, bool p_invisible = false) { #ifdef BVH_VERBOSE_TREE VERBOSE_PRINT("\nitem_add BEFORE"); _debug_recursive_print_tree(p_tree_id); VERBOSE_PRINT("\n"); #endif BVHABB_CLASS abb; abb.from(p_aabb); // NOTE that we do not expand the AABB for the first create even if // leaf expansion is switched on. This is for two reasons: // (1) We don't know if this object will move in future, in which case a non-expanded // bound would be better... // (2) We don't yet know how many objects will be paired, which is used to modify // the expansion margin. // handle to be filled with the new item ref BVHHandle handle; // ref id easier to pass around than handle uint32_t ref_id; // this should never fail ItemRef *ref = _refs.request(ref_id); // the extra data should be parallel list to the references uint32_t extra_id; ItemExtra *extra = _extra.request(extra_id); BVH_ASSERT(extra_id == ref_id); // pairs info if (USE_PAIRS) { uint32_t pairs_id; ItemPairs *pairs = _pairs.request(pairs_id); pairs->clear(); BVH_ASSERT(pairs_id == ref_id); } extra->subindex = p_subindex; extra->userdata = p_userdata; extra->last_updated_tick = 0; // add an active reference to the list for slow incremental optimize // this list must be kept in sync with the references as they are added or removed. extra->active_ref_id = _active_refs.size(); _active_refs.push_back(ref_id); extra->tree_id = p_tree_id; extra->tree_collision_mask = p_tree_collision_mask; // assign to handle to return handle.set_id(ref_id); create_root_node(p_tree_id); // we must choose where to add to tree if (p_active) { ref->tnode_id = _logic_choose_item_add_node(_root_node_id[p_tree_id], abb); bool refit = _node_add_item(ref->tnode_id, ref_id, abb); if (refit) { // only need to refit from the parent const TNode &add_node = _nodes[ref->tnode_id]; if (add_node.parent_id != BVHCommon::INVALID) { refit_upward_and_balance(add_node.parent_id, p_tree_id); } } } else { ref->set_inactive(); } #ifdef BVH_VERBOSE // memory use int mem = _refs.estimate_memory_use(); mem += _nodes.estimate_memory_use(); String sz = _debug_aabb_to_string(abb); VERBOSE_PRINT("\titem_add [" + itos(ref_id) + "] " + itos(_refs.used_size()) + " refs,\t" + itos(_nodes.used_size()) + " nodes " + sz); VERBOSE_PRINT("mem use : " + itos(mem) + ", num nodes reserved : " + itos(_nodes.reserved_size())); #endif return handle; } void _debug_print_refs() { #ifdef BVH_VERBOSE_TREE print_line("refs....."); for (int n = 0; n < _refs.size(); n++) { const ItemRef &ref = _refs[n]; print_line("tnode_id " + itos(ref.tnode_id) + ", item_id " + itos(ref.item_id)); } #endif } // returns false if noop bool item_move(BVHHandle p_handle, const BOUNDS &p_aabb) { uint32_t ref_id = p_handle.id(); // get the reference ItemRef &ref = _refs[ref_id]; if (!ref.is_active()) { return false; } BVHABB_CLASS abb; abb.from(p_aabb); #ifdef BVH_EXPAND_LEAF_AABBS if (USE_PAIRS) { // scale the pairing expansion by the number of pairs. abb.expand(_pairs[ref_id].scale_expansion_margin(_pairing_expansion)); } else { abb.expand(_pairing_expansion); } #endif BVH_ASSERT(ref.tnode_id != BVHCommon::INVALID); TNode &tnode = _nodes[ref.tnode_id]; // does it fit within the current leaf aabb? if (tnode.aabb.is_other_within(abb)) { // do nothing .. fast path .. not moved enough to need refit // however we WILL update the exact aabb in the leaf, as this will be needed // for accurate collision detection TLeaf &leaf = _node_get_leaf(tnode); BVHABB_CLASS &leaf_abb = leaf.get_aabb(ref.item_id); // no change? #ifdef BVH_EXPAND_LEAF_AABBS BOUNDS leaf_aabb; leaf_abb.to(leaf_aabb); // This test should pass in a lot of cases, and by returning false we can avoid // collision pairing checks later, which greatly reduces processing. if (expanded_aabb_encloses_not_shrink(leaf_aabb, p_aabb)) { return false; } #else if (leaf_abb == abb) { return false; } #endif #ifdef BVH_VERBOSE_MOVES print_line("item_move " + itos(p_handle.id()) + "(within tnode aabb) : " + _debug_aabb_to_string(abb)); #endif leaf_abb = abb; _integrity_check_all(); return true; } #ifdef BVH_VERBOSE_MOVES print_line("item_move " + itos(p_handle.id()) + "(outside tnode aabb) : " + _debug_aabb_to_string(abb)); #endif uint32_t tree_id = _handle_get_tree_id(p_handle); // remove and reinsert node_remove_item(ref_id, tree_id); // we must choose where to add to tree ref.tnode_id = _logic_choose_item_add_node(_root_node_id[tree_id], abb); // add to the tree bool needs_refit = _node_add_item(ref.tnode_id, ref_id, abb); // only need to refit from the PARENT if (needs_refit) { // only need to refit from the parent const TNode &add_node = _nodes[ref.tnode_id]; if (add_node.parent_id != BVHCommon::INVALID) { // not sure we need to rebalance all the time, this can be done less often refit_upward(add_node.parent_id); } //refit_upward_and_balance(add_node.parent_id); } return true; } void item_remove(BVHHandle p_handle) { uint32_t ref_id = p_handle.id(); uint32_t tree_id = _handle_get_tree_id(p_handle); VERBOSE_PRINT("item_remove [" + itos(ref_id) + "] "); //////////////////////////////////////// // remove the active reference from the list for slow incremental optimize // this list must be kept in sync with the references as they are added or removed. uint32_t active_ref_id = _extra[ref_id].active_ref_id; uint32_t ref_id_moved_back = _active_refs[_active_refs.size() - 1]; // swap back and decrement for fast unordered remove _active_refs[active_ref_id] = ref_id_moved_back; _active_refs.resize(_active_refs.size() - 1); // keep the moved active reference up to date _extra[ref_id_moved_back].active_ref_id = active_ref_id; //////////////////////////////////////// // remove the item from the node (only if active) if (_refs[ref_id].is_active()) { node_remove_item(ref_id, tree_id); } // remove the item reference _refs.free(ref_id); _extra.free(ref_id); if (USE_PAIRS) { _pairs.free(ref_id); } // don't think refit_all is necessary? //refit_all(_tree_id); #ifdef BVH_VERBOSE_TREE _debug_recursive_print_tree(tree_id); #endif } // returns success bool item_activate(BVHHandle p_handle, const BOUNDS &p_aabb) { uint32_t ref_id = p_handle.id(); ItemRef &ref = _refs[ref_id]; if (ref.is_active()) { // noop return false; } // add to tree BVHABB_CLASS abb; abb.from(p_aabb); uint32_t tree_id = _handle_get_tree_id(p_handle); // we must choose where to add to tree ref.tnode_id = _logic_choose_item_add_node(_root_node_id[tree_id], abb); _node_add_item(ref.tnode_id, ref_id, abb); refit_upward_and_balance(ref.tnode_id, tree_id); return true; } // returns success bool item_deactivate(BVHHandle p_handle) { uint32_t ref_id = p_handle.id(); ItemRef &ref = _refs[ref_id]; if (!ref.is_active()) { // noop return false; } uint32_t tree_id = _handle_get_tree_id(p_handle); // remove from tree BVHABB_CLASS abb; node_remove_item(ref_id, tree_id, &abb); // mark as inactive ref.set_inactive(); return true; } bool item_get_active(BVHHandle p_handle) const { uint32_t ref_id = p_handle.id(); const ItemRef &ref = _refs[ref_id]; return ref.is_active(); } // during collision testing, we want to set the mask and whether pairable for the item testing from void item_fill_cullparams(BVHHandle p_handle, CullParams &r_params) const { uint32_t ref_id = p_handle.id(); const ItemExtra &extra = _extra[ref_id]; // which trees does this item want to collide detect against? r_params.tree_collision_mask = extra.tree_collision_mask; // The testing user defined object is passed to the user defined cull check function // for masks etc. This is usually a dummy object of type T with masks set. // However, if not using the cull_check callback (i.e. returning true), you can pass // a nullptr instead of dummy object, as it will not be used. r_params.tester = extra.userdata; } bool item_is_pairable(const BVHHandle &p_handle) { uint32_t ref_id = p_handle.id(); const ItemExtra &extra = _extra[ref_id]; return extra.pairable != 0; } void item_get_ABB(const BVHHandle &p_handle, BVHABB_CLASS &r_abb) { // change tree? uint32_t ref_id = p_handle.id(); const ItemRef &ref = _refs[ref_id]; TNode &tnode = _nodes[ref.tnode_id]; TLeaf &leaf = _node_get_leaf(tnode); r_abb = leaf.get_aabb(ref.item_id); } bool item_set_tree(const BVHHandle &p_handle, uint32_t p_tree_id, uint32_t p_tree_collision_mask) { // change tree? uint32_t ref_id = p_handle.id(); ItemExtra &ex = _extra[ref_id]; ItemRef &ref = _refs[ref_id]; bool active = ref.is_active(); bool tree_changed = ex.tree_id != p_tree_id; bool mask_changed = ex.tree_collision_mask != p_tree_collision_mask; bool state_changed = tree_changed | mask_changed; // Keep an eye on this for bugs of not noticing changes to objects, // especially when changing client user masks that will not be detected as a change // in the BVH. You may need to force a collision check in this case with recheck_pairs(). if (active && (tree_changed | mask_changed)) { // record abb TNode &tnode = _nodes[ref.tnode_id]; TLeaf &leaf = _node_get_leaf(tnode); BVHABB_CLASS abb = leaf.get_aabb(ref.item_id); // make sure current tree is correct prior to changing uint32_t tree_id = _handle_get_tree_id(p_handle); // remove from old tree node_remove_item(ref_id, tree_id); // we must set the pairable AFTER getting the current tree // because the pairable status determines which tree ex.tree_id = p_tree_id; ex.tree_collision_mask = p_tree_collision_mask; // add to new tree tree_id = _handle_get_tree_id(p_handle); create_root_node(tree_id); // we must choose where to add to tree ref.tnode_id = _logic_choose_item_add_node(_root_node_id[tree_id], abb); bool needs_refit = _node_add_item(ref.tnode_id, ref_id, abb); // only need to refit from the PARENT if (needs_refit) { // only need to refit from the parent const TNode &add_node = _nodes[ref.tnode_id]; if (add_node.parent_id != BVHCommon::INVALID) { refit_upward_and_balance(add_node.parent_id, tree_id); } } } else { // always keep this up to date ex.tree_id = p_tree_id; ex.tree_collision_mask = p_tree_collision_mask; } return state_changed; } void incremental_optimize() { // first update all aabbs as one off step.. // this is cheaper than doing it on each move as each leaf may get touched multiple times // in a frame. for (int n = 0; n < NUM_TREES; n++) { if (_root_node_id[n] != BVHCommon::INVALID) { refit_branch(_root_node_id[n]); } } // now do small section reinserting to get things moving // gradually, and keep items in the right leaf if (_current_active_ref >= _active_refs.size()) { _current_active_ref = 0; } // special case if (!_active_refs.size()) { return; } uint32_t ref_id = _active_refs[_current_active_ref++]; _logic_item_remove_and_reinsert(ref_id); #ifdef BVH_VERBOSE /* // memory use int mem_refs = _refs.estimate_memory_use(); int mem_nodes = _nodes.estimate_memory_use(); int mem_leaves = _leaves.estimate_memory_use(); String sz; sz += "mem_refs : " + itos(mem_refs) + " "; sz += "mem_nodes : " + itos(mem_nodes) + " "; sz += "mem_leaves : " + itos(mem_leaves) + " "; sz += ", num nodes : " + itos(_nodes.size()); print_line(sz); */ #endif } void update() { incremental_optimize(); // keep the expansion values up to date with the world bound //#define BVH_ALLOW_AUTO_EXPANSION #ifdef BVH_ALLOW_AUTO_EXPANSION if (_auto_node_expansion || _auto_pairing_expansion) { BVHABB_CLASS world_bound; world_bound.set_to_max_opposite_extents(); bool bound_valid = false; for (int n = 0; n < NUM_TREES; n++) { uint32_t node_id = _root_node_id[n]; if (node_id != BVHCommon::INVALID) { world_bound.merge(_nodes[node_id].aabb); bound_valid = true; } } // if there are no nodes, do nothing, but if there are... if (bound_valid) { BOUNDS bb; world_bound.to(bb); real_t size = bb.get_longest_axis_size(); // automatic AI decision for best parameters. // These can be overridden in project settings. // these magic numbers are determined by experiment if (_auto_node_expansion) { _node_expansion = size * 0.025; } if (_auto_pairing_expansion) { _pairing_expansion = size * 0.009; } } } #endif } void params_set_pairing_expansion(real_t p_value) { if (p_value < 0.0) { #ifdef BVH_ALLOW_AUTO_EXPANSION _auto_pairing_expansion = true; #endif return; } #ifdef BVH_ALLOW_AUTO_EXPANSION _auto_pairing_expansion = false; #endif _pairing_expansion = p_value; // calculate shrinking threshold const real_t fudge_factor = 1.1; _aabb_shrinkage_threshold = _pairing_expansion * POINT::AXIS_COUNT * 2.0 * fudge_factor; } // This routine is not just an enclose check, it also checks for special case of shrinkage bool expanded_aabb_encloses_not_shrink(const BOUNDS &p_expanded_aabb, const BOUNDS &p_aabb) const { if (!p_expanded_aabb.encloses(p_aabb)) { return false; } // Check for special case of shrinkage. If the aabb has shrunk // significantly we want to create a new expanded bound, because // the previous expanded bound will have diverged significantly. const POINT &exp_size = p_expanded_aabb.size; const POINT &new_size = p_aabb.size; real_t exp_l = 0.0; real_t new_l = 0.0; for (int i = 0; i < POINT::AXIS_COUNT; ++i) { exp_l += exp_size[i]; new_l += new_size[i]; } // is difference above some metric real_t diff = exp_l - new_l; if (diff < _aabb_shrinkage_threshold) { return true; } return false; }